Automatic washing machine



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AUTOMATIC WASHING MACHINE June 30, 1942. I

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Filed Nov. 25, 1958 13 Sheets-Sheet 1O IILUM Za J.

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AUTOMATIC WASHING MACHINE Filed Nov. 25, 1938 13 Sheets-Sheet 11 five/22 07:

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Patented June 30, 1942 UNITED STATES PATENT OFFICE AUTOMATIC WASHING MACHINE Henry W. Alton-fer, Peoria, Ill. Application November 23,1938, Serial No. 241,901 a Claims. (01. 68-148) This invention relates to washing machinesof the automatic cycle type wherein the several washing, rinsing and drying operations are per-. formed in proper sequence automatically.

that the invention may be applied in various other types of machines, and'it willbe understood that the applicant is merely describing a preferred embodiment of his invention.

Domestic washing machines generally have been developed to a high state of perfection over an extensive period of years, as manually operable washer units having a swinging wringer attached thereto. Such machines are usually located in basements adjacent rinse tubs; water faucets and floor drains and their use involves almost the continuous presence of the operator for the multiplicity of operations involved in the task of home laundering. Moreover, their operation usually incurs considerable incidental immersion of the operators hands in the various tubs of water, which with the accidental spilling of water, etc., generally makes washing a damp, messy task. Moreover, these conventional type washers have many faults which are generally recognized, such as:

a. Too small a volume of water for the quantity of clothes washed, a condition which contributes to poor, high-bacteria washing results.

1). Too small a volume of rinse water, usually of improper temperature and often the wrong kind of rinse, which with improper flushing of the garments in the rinse water, usually results in the improper rinsing of the clothes.

0. Ineiiective, destructive and dangerous wringing of the clothes with conventional roll wringers.

All of these points have been given careful and thoughtful consideration by the applicant in the development of this'invention, and later it will be explained how these objections have been eliminated in this device. i

Applicant is aware that there are automatic or semiautomatic machines of this general typeon the market and has given these machines careful study and consideration. Thesemachines generally fail to give the desired results for on or more of the following reasons:

a. Inefiective washing action.

I). Inefiective wringing. I

c. Small volume of wash and rinse water.

d. Wasteful use of soap, bluing, water and heat.

e. Expensive plumbing for installation.

I. Large hot water supply requirements.

g. Vibration incident to the extractor operation.

h. The complete washing cycle requires too much time, slow.

i. Unsanitary.- Interior of the machine cannot be completely cleaned.

Later the applicant will explain how these 011-. jections have been largely eliminated by the present invention. With full consideration and appreciation of the foregoing, the particular object of this in vention is to provide a complete self-contained washing machine which will automatically perform the full cycle of necessary power washing, power rinsing and centrifugal drying operations rapidly, efiectively and quietly.

' while it is in operation so as to make the washing and rinsing operations more effective.

' And a still further object is to provide means and structure in a machine of the'class described whereby the tub and tanks of the machine may be manually scrubbed and cleansed to make the machine clean and sanitary.

Fig. 1 is a general isometric view of the washer showing. the tub and tanks in dotted outline;

Fig. 2 is a top sectional plan view of the washer with the cabinet top removed to show the tanks;

Fig. 3 is an enlarged bottom plan view showing the arrangement of the mechanism and the piping to the tanks; I

4 is an enlarged broken elevation view partly in section, showing the arrangement of the mechanism, the distribution and tanks;

Fig. 4 is an enlarged sectional detail of .a check valve, later explained.

5' is an enlarged side elevation view of the motor and gear case, showing the solenoid controls in position; I

Fig. 6 is an enlarged plan view of the gear case as it appears on the section lines6-'--6 of Fig.5.

Fig. 'I is an enlarged sectional elevation view of the gear case, showing the interlor mechanism as it appears on the section lines 1-1 of Fig. 6; Fig. 8 is an enlarged'plan view or the pump.

pump motor and distributor valve partly in section to better showthe arrangement;

Fig. 9 is a sectional plan view of the single revolution-clutch used in the distributor system as it would appear on the section lines 9-9 of Fig. 8;

Fig. '10 is an enlarged elevation view of the solenoid escape plunger used in connection with the one revolution clutch as it would appear from the section lines ill-ill of Fig. 8;

Fig. 11 is an enlarged broken side elevation view of the pump and distributor system partly in section, as it appears from the lines il-ll of Fig. 8;

Fig. 12 is an end elevation view of the same mechanism as shown in Figs. 8 and 11;

Fig. 13 is an enlarged sectional elevation view of the tub, tub cover and support spider;

Fig. 14 is a broken sectional plan view showing the mounting of the cover in the body of the tub as it appears on the lines M-M of Fig. 13;

Fig. 15 is a broken sectional plan view showing the mounting of the tub on the support spider as it appears on the section lines li 5 of Fig. 13;

Fig. 16 is an enlarged broken elevation view partially in section, showing details of the spring support for the tub and mechanism;

Fig. 1'? is a sectional plan view showing details tub- 32. This arrangement and construction utilizes the weight ofthe water 'or fluid in the respective tanks or compartments to stabilize the cabinet and the entire unit especially during the centrifugal drying operation of thetub. Furthermore, the enlarged capacity of each of the tanks relative to the much reduced capacity of the tub, supplies the needed quantity of water for washing, while utilizing a minimum quantity of water in the tub at one time, which not only permits high speed rotation of the small tub for extraction without substantial vibration, but also insures rapid changing of the washing fluid or water during the washing action, with maximum sanitary effects. 7

The lids on the tanks being substantially as large as the tanks, enables the operator to thoroughly cleanse the interior of the tanks so as to keep them sanitary and clean. This is very important in a domestic washing machine and particularly in'the type disclosed wherein the wash and rinse waters are circulated through the tub of the cycle control mechanism as they would appear on the sectionlines i'I-i'l of Fig. 18;

Fig. 18 is an enlarged elevation view. of the cycle control mechanism partly in section;

Fig. 19 is a plan view of the control knob showing the time markings;

Figs. 20 to 25 are plan-views of the various control disks for the different cycles. which will later be described in detail;

Fig. 26 is a diagrammatic outline drawing to better show the various electrical and hydraulic controls which will later be described.

Fig. 1 shows a general view of the washer which is enclosed within a cabinet designated as a whole by the numeral 3|. Centrally located in the cabinet, as indicated in dotted outline, is a vertical axis tub 32 enclosed within a casing, as will later be'shown and described. All washing, rinsing and centrifugal drying operations are done in this tub and without attention from the. operator, by means which will later be disclosed.

Enclosed within the cabinet, as shown in dotted outline, are four substantially rectangular tanks 33, 34, and 36, each having a top opening lid 33, 34', 35' and 3B. The two tanks onone end are for wash water and, of course, with the top opening lids this wash water may be prepared by the addition of water softener and soap for the proper cleansing of clothes. Although not shown, it is obvious that heating means might be introduced to these tanks, for instance, as tubular electrical heating elements, and thus is provided mean whereby the, complete washing supply of proper wash water, both as to temperature and soap content, may be prepared.

The tanks in the opposite end are for rinse waters, the one normally being a -moderately warm rinse andthe other a cold rinse to which bluing has been added. Thus means is provided whereby the complete washing supply of proper rinse waters are available for use in the machine.

As shown in Figs. 1 and 2, the tanks or compartments 33, 34, 35 and 36 are symmetrically arranged in pairs on opposite sides of the washing tub 32, and extend downwardly in the cabinet and clothes. As a matter of fact, this cleansing of the tanks is so important that a long handled brush is supplied to the operator so as to better enable her to keep the tanks sweet and clean.

Now referring to Fig. 4, which is a vertical sectional elevation view, attention is directed to the angle iron support rail 31 from which the entire tub mechanism is'supported. This support rail extends completely around the central section of the cabinet and is riveted securely therein. Attached to this angle iron support 31 are coiled tension. support springs 38, as is better shown in Fig. 16. The opposite ends of the springs 38 attach to channel members 39 which in turn at- 4 the sump 45' and the drain tube I39 is a hollow Fig. 6, the motor has a double shaft extension,

. 3| to points appreciably below the bottom of the tach to a central cone support member 40, as shown. On the top of this cone support member is an annular supporting bearing 4i which supports the main drive shaft 58 and the gear case cover 43', as best shown in Fig. 16. The gear case 43 hangs on the gear case cover 43' and is driven by a motor 44 attached to the gear case by brackets, as best shown in Fig. '7. On top of the main tub shaft 58 is a tub support spider 42 which supports the tub 32, as will later be described in detail. Around the tub' 32 is a water receiver casing 45 which catches'the water discharged from the tub 32, draining it off through the sump 45'. In the sump 45 is a screen I58 which will catch buttons, pins and other foreign matter. Also at the juncture of ball check valve as shown in Fig. 4 which prevents water from the tanks backing up in sump.l5'.

From the foreg ing it will be understood that i the tub and tub drive mechanism is .yieldingly supported in the center of the cabinet by a,

unique spring support which is designed to elimi nate vibration incidentto the high rotational speeds of the tub during the extraction cycle.

Now referring to Figs. 5, 6 and 7 showing the gear case mechanism, it will be seen that the drive motor 44 is supported on the gear case 43 .by conventional brackets 43. As will ,be seen in and on one end of the shaft a pulley 4! drives a belt 48 to a drive pulley 49 loosely journaled on the spinner drive shaft 53. The pulley 49 transmits rotational movement to the spinner drive shaft 53 through a disk clutch 50 urged into contact with a brake pulley 5| by the friction clutch spring 5i. The brake pulley 51 is keyed to the shaft 53 and thereby imparts rotational moveon the worm shaft 62.

2,287,927 ment to the shaft. On the spinner drive shaft 53 and attached thereto is a helical drive gear 54 which meshes with a mating helical gear 55 on the tub shaft 58, as clearly. shown in Fig. I. On the inner end of the spinner drive shaft 53 is a ball thrust bearing 53' which absorbs the thrust from the helical gears 54 and.55. It will be obvious that the spinner drive shaft 53 is rotated at all times. However, when. the tub is clutched in for extraction,' as will later be explained, the spinner drive friction clutch permits considerable slipping movement, thereby providing means whereby the tub is properly accelerated to its extraction speed.

Now referring to Fig. '1, it will be seen that a fixed clutch member 56 is attached to the tub shaft 58 above the driven helical gear 55 and a jaw clutch 51 is slidably mounted on splines 58' of the tub shaft 58 for clutching movement between the clutch member 56 for extractor rotation of the tub and the clutch pinion 13 which is for oscillating action of the tub, as will later be explained.

On the opposite end of the motor 44, as shown in Fig. 6, is another driven pulley 59 which drives a V-belt 60 to a driven pulley 6l fixedly mounted The worm shaft 62 is journaled in the gear case 43, driving a worm 63 fixed to the shaft- On the inside end of the worm shaft 62 is a ball thrust bearing 64-having an adjustment screw 65. The worm 63 meshes in and drives a worm gear 66 mounted on a vertical worm gear shaft 61, on the upper end.

of which is fixedly mounted an eccentric 68. This eccentric 68 through a connecting rod 69 attached by a pin 10 drives a segment gear 1I mounted on a pin 12. The segment gear 12 continuously oscillates the clutch pinion 13 which was mentioned in connection with the clutch 51.

From the foregoing it will be apparent that when the clutch 51 is in lowermost position, as shown in Fig. 7, the tub shaft 58 will be rapidly rotated, thus causing extractor or spinner action in the washer tub 32. When the clutch 51 is moved to upper position and meshes in the clutch pinion 13, the tub shaft will be oscillated, thereby causing oscillatory washing action in the tub 32.

Now referring to Fig. 5, a conventional solenoid 14 is mounted on the side of the gear case 43. The plunger of the solenoid 15 is connected by a pin 16 to a bell crank". It will be obvious that when the solenoid is energized to pull plunger 15 inward, the bell crank 11 will lift the link 18 and the bolt 19, which will clamp the brake 52 on the brake band and thus stop rotation of the shaft 53 and the tub shaft 58 on which is mounted the tub 32. This action is permitted by means of the friction clu ch 50. It

will be obvious that the foregoing st cture will permit the tub to be stopped. Thespring 19'. will cause the brake band 52 to be released when the solenoid 14 is de-energized.

Again, referring to Fig.5, ot{ the gear case cover 43' there is'mounted dual solenoids, 8'0 and 8| connected by a link 82 pivotally attached to a bell crank lever 83 mounted on a pivot pin 80 which has a bell crank shift lever 85 mounted on its inner end, as shown in Fig. 7. It will be apparent that as the solenoid 80 is energized,'

effective tub .structure 58 and thereupon the tub will be accelerated rapidly into the spinning or extraction cycle.

From the foregoing it will be apparent that" means is provided to control the clutch 51 in order to effect either oscillating or rotating action of the tub.

Now referring to Figs. 13, 14, and 15, it will be seen that the tub support spider 421s rigidly mounted on the tapered keyed end 86 of the shaft 58 and that the tub 32 is rigidly attached thereon by the crown nut 81. The tub support spider has threearms, the ends of which are surrounded by U-shaped grip rubbers 88, as clearly shown in Fig. 15. These grip rubbers fit securely into the hollow U-shaped tub baffles 89, as shown. It will be apparent that by this structure there is provided a firm yet cushioned mounting-of the tub 32 on the spider 42.

The lid 90 of the tub 32 is mounted by means of lid brackets 9I having projections which ex-.

tend. through rubber lid grommets 92. The inside face of the grommetsabut against the curved rim 90' and thus provide an annular discharge passage 93 for the water ejected by the centrifugal action of the tub when on the ;spin-- ning cycle. The lid 90 has a rather large circular opening to facilitate putting in and taking out clothes as well as to permit easy access to the interior of the tub for all necessary scrubbing or cleansing. The lid being mounted in rubber grommets, as shown and described, is held in firm cushioned position without any metallic contact with the tub, a structure which is both effective and quiet. The curved rim 90' of the lid 90 throws the discharged water downward well within the receiver casing 45 where it is quickly drained off through the sump- 45'.

From the foregoing it will beap'parent that an is provided wherein clothes may be washed by the oscillatory movement of the tub and the water effectively extracted by the rapid rotation of the tub and centrifugal action.

Now referring to Fig. 8,'a fractional horse power pump motor 94 is connected by a flexible coupling 95 to a stainless steel pump shaft 96 on which isv mounted dual pump rotors 91 and 98. These rotors have separate and distinct housings and, therefore, for all practical purposes they are two distinct pumps, the purpose for which will later be described. The pump shaft 96 is sealed in the pump housing by pump packing glands. 99 and I00.

On the outer end of the pump shaft 96 and attached to it by a tongue and groove connection is a worm shaft IOI mounted in a worm gear casing I02. -The thrust of this worm shaft is .mounted a drive clutch member I05.

Now referring to Fig. 9, it will be seen that this clutch is a rather conventional form of one revolution clutch wherein the member I05 is the drive clutch member and the sliding member I06'is the driven member. The slide clutch I06 slides between fixed washers I08 and has a tooth I01 for driving engagement in the openings of the clutch member ms. The slide member ns is normally urged into clutching engagement by spring H0 and is permitted to slide between the washers I08 by a slotted opening I01f around the shaft I04. However, a throwout arm I09 plunger projection I I I.

projecting outward, as'shown in Fig. 9, has come in contact with a solenoid plunger projection III mounted on the solenoid plunger H2, and by this contact the clutch I has slid outward out of engagement with clutch I05.

, spams-r Now again referring to Figs. 8 and 10, it will the clutch I00 will, therefore, go one revolution until the throw-out arm I09 again strikes the action of the clutch is provided for by means of the spring 4 on the solenoid plunger II2 which urges the plunger outward, as shown. It will, therefore, be apparent that when the solenoid H5 is energized momentarily, the plunger II2 will be drawn downward and then the spring II4 will immediately urge it outward to its position where the plunger projection III will again strike the throw-out arm I09.

From the above description it will be apparen that mechanism has been provided whereby a single revolution of the clutch I00 is obtained by momentarily energizing the solenoid II5.

Now referring to Figs. l2 and 8, journaled on top ofthe shaft I04 and driven by the slide clutch I00 is the drive plate IIO of a conventional Geneva motion mechanism consisting of the drive V plate H0 and the driven plate II1. This type of mechanism is well-known in the art and will not be described any further than to explain that while the drive member is revolving one revolution, the driven member is driven a part of one revolution and in the meantime is held stationary. In the mechanism being described the drive plate I I0 has a drive pin IIO which meshes indrive slots II9 being held in proper position by the lock ring I20 as engaged by the lock segment section I2I on the-driven member II1. It will be obvious that when the member IIO revolves one revolution, the driven member H1 is 'driven one-quarter revolution, and during all this period the member H1 is either locked in a definite position or is quickly rotating one-quarter of a revolution. The adaptation of this arrangement will be later disclosed in connection yvith a four-outlet valve.

Now referring to Figs. 8 and 12, it will be seen that the driven plate H1 is feather keyed on a shaft I22 slidable on a keyway I09, which actually is a valve stem shaft extending through a valve cover-plate I23 and attached to a conical valve plug I29. The valve cover-plate I23 not only serves as a cover-plate. but also as a mounting bracketfor the solenoid II 5 and .a journal bracket for the shaft I04.

the extended portion of the shaft I22 from the interior of the valve body I25. The valve plug I20 is urged downward into sealed contact with the valve body I 25 by a compression spring I24,

' as shown. It will be noted that the valve seat plug I20 has apartition I28 dividing the valve into two separate divisions. In the upper. division there is a s'ingle'valve seat discharge opensection of the valve has an I34, I30 and m.

The valve shaft I22 This single revolution is feather keyed to the. valve plug I20 by a keyway I and pinned to a drain plug in having a matched opening m' with the inlet opening up ofthe valve plug m.

It will be apparent that when the shaft I22 is depressed against the compression spring I12,-

the drain plug- "I will be forced away from seal contact with the valve plug I 20 and thereby open all four inlet pipe lines I32, I34, I and I30, permitting them all to drain simultaneously through the manifold I40. Thus valve means is provided to drain the entire machine as will later, be explained.

It will be noted that the valve body I25 has integral with it a pump casing I20 and an from the receiver casing is taken through the pump 91 and discharged through the outlet manifold tube MI and into the top section of the valve I25 and through the discharge opening I29 to anyone .of four outlet pipes I3I, I33, I35 and I31. 1

By referring to Fig. 26, inwhich the arrangement is shown diagrammatically, it will be clearly shown that pump 91 has an inlet pipe I30 from the tub casing sump 45' and the pump discharges water. through either of four pipe lines, namely I3I -to the first wash tank 33, I33 to the second wash tank 34, I35 to the first rinse tank 35, and 131- to the second rinse tank 30. Also it will be clearly shown and understood that the pump 90 has four inlet pipe lines, namely I32 from the first wash tank '33, I34 from the second wash tank 34, I30 from the first rinse tank 35, and I30 from the secondrinse tank 30. The pump 90 is discharged through the circulator discharge tube I42 and out thenozzlecheck valve I44, as shown in Fig. 2. By means of this check valve the discharge of water from It also has a conventional'valve shaft packing gland I23 which seals the pump is stopped by energizing the solenoid.

Now referring to-Figs. 4, 8, 11 and 26, and continuing the explanation of how the machine is drained, it has been explained how depressing the shaft I22 and the drain plug I1I opens up-the four inlet pipelines I32, I34, I30 and I30 to the manifold I40 and thus permits complete draining of the machine.

In Fig. 11 is shown how this shaft I22 may be depressed. A foot lever I13-pivoted at I14 has a foot pad I15 extending beyond the lower edge of the cabinet 3|, as clearly shown in Fig. 1.

when this foot lever is depressed, it is held by a catch latch I10 catching under the lower edge of the cabinet, being actuated by the tension On the pressure end of the lever-I10 is a leaf spring I00 pivoted on a bracket. IOI and bearing against a' pin I19. This leaf spring contacts the trip pin I03 of a quick action or microswitch I32 on the bracket I9I. Thus, when the lever I13 is operated to drain the machine the micro-switch closes the circuit to the pump motor 94 and assures that the pump will operate for the draining operation.

As shown diagrammatically in Fig. 26, this draining isaccomplished by merely attaching a drain hose I83 to the nozzle I43. Also, as shown in Figs.'4 and 26, a manually operable drain I45 is provided, and this drain at the lowest point in the pipe system assures complete draining of the machine.

Now referring to Fig. 18 in which is shown the control apparatus, a small fractional horsepower motor I46 drives a shaft I48 through a conventional speed reducer I41.

Keyed to thi shaft I48 by the coupling I46 is a controller shaft I50 which has a series of cam structures wherein a series of notches or lugs are made to contact with a spring arm on which is carried an electrical contact point which matches with a similar contact point on a stationary arm. Thus referring to Fig. 23, the stationary arm I6I, with its contact point I63, has broken contact with the point I64 on the spring arm I62 because the cam disk at this point has permitted the spring arm I62 to spring downward, thus breaking the contact. It is obvious that when the cam under the spring arm I62 rotates clockwise the contact points I63 and I64 will be closed and the circuit 5' made.

In some cases a cam disk is made to handle more, than one electric circuit, as is illustrated in Fig. 20. Here the spring arms are I65 and I66 working in harmony by the connector member I61 and the stationary arm with double contact points is I68 positioned between the spring arms I65- and I66. This method of controlling elec-v trical circuits by cams of this character is well known and applicant does not feel that a detailed description of each of the cams as illustrated is either necessary or advisable. In each of the cam disks illustrated the electrical circuit or the apparatus it controls has been plainly marked and to anyone skilled in the .art, by referring to the diagrammatic outline in Fig. 26, the manner and means of controlling the circuit will be well understood. Applicant again desires to point out that the cam disks illustrated under the figurenumbers are referred to by the same number primed as numerals in Figs. 18 and 26.

Now referring to Fig. 1'7 wherein the control- -after the control motor (carries out its complete cycle of operations.

Mounted above the controller housing on the top of the cabinet, as shown in Figs. 18 and 19, is a control dial I54 with knob I54. This dial is connected to a rheostat I55 by a shaft I56, the

rheostat being connected in the motor circuit I46" of the control motor I46. The dial is marked in numerals 20 to 34 representing the time in minutes .for the complete washing cycle. Thus, by adjusting the dial I54 and the rheostat I55, the operator controls the speed of themotor I46 and the time of washing to suit the nature of the wash.

In Fig. 26 is illustrated diagrammatically a main control switch I58 (otherwisenot shown) whereby the main electrical circuit to the washer may be disconnected. I

It is believed that the foregoing description will clearly and completely disclose the. structure of the. machine whereby 'the complete cycle of washing, rinsing and drying is done automatically., This sequence of operationswill now be explained in detail.

Sequence of operations 1. Start machine by depressing starter button 2. Pump water from first wash tank 33 into tub 32 and from receiver casing back into tank 33. Start. tub on oscillating washing motion. Run seven minutes.

3. Tub stops. Water stops from water tank 33 to tub by check valve I44. Continue'pumping from receiver casing to tank 33,

4. Tub starts on extractor spinning action. Runs one minute.

5. Stop extractor spinning of tub by stopping motor 44 and applying brake 52 by solenoid I4.

6. Pump water from second wash tank 34 into tub and from receiver casing 45 back into tank 34. Start tub on oscillating washing action. Run ten minutes.

7. Tub 34 stops. Water stops from second Wash tank 34 into tub by check valve I44. Continue pumping from receiver casing back into tank 34.

8. Tub starts on extractor spinning action. Runs one minute.

9. Stop spinning tub by stopping motor 44 and applying brake 52.

10. Pump water from first rinse tank 35 into tub and from receiver casing back into tank 35. Start tub on oscillating rinsing action. Run

three minutes.

tank 36 to container by check valveal44. Continue pumping from receiver casing into tank 36.

16. Start tub on extractor spinning action. Run. one minute.

17. Stop spinning of tub by stopping motor 44 and applying brake 52. Total time, including stopping apparatus, controllable through control dial I54 and knob I54 from 20 to 34 minutes.

With the foregoing explanation the structure and operation of the machine will be fully understood. Applicant now desires to explain and pointout that by the means as described the following definite results are accomplished:

a. Effective washing of clothes is accomplished by the oscillatory movement of the vertical axis tub with baflles or other washing means therein.

12. Unusually effective wringing results are ac-' complished by the'high rotational speed developed by the tub during the extraction cycle. The

wringing results thus accomplished are far in advance of the usual results in domestic washing machines. materially becauseof the effective wringing re- Slllts thus accomplished.

c. The circulation of a large volume of both wash and rinse water during the two-power washing andtwo-power rinsing operations is a definite advance' over' conventional washing methods.

-d. No waste of water, soap, bluing' or heat. The optimum in economical arrangement.

Drying time is cut downvery rotation of the tub and its agitating means, a

tank having a capacity many times that of the tub adapted to contain the complete washing supply of cleansing liquid, a pump for forcing the liquid from said tank to the tub during the oscillatory phase of the movement of thetub, a

second pump for drawing the. liquid escaping from thetub away therefrom and back to said tank whereby rapid circulation of the cleansing is effected during the said oscillating phase of e, The machine requires no expensiveplumbing or in fact any unusual installation expense.

I. No large hot water supply requirements are necessary in the operation of this machine.

g. The operation of the machine is very smooth I and quiet. Vibration almost entirely eliminated because of the unique resilient support of the small tub with minimum chances for vibration and the fact that the entire machine when filled with water in the supply tanks is sufllciently heavy to absorb practically all vibration.

. ciple of operation of the machine is susceptible to various modifications and the applicant does not desire to be limited in any way except as imposed by the following claims.

I claim:

1. A self-contained laundry apparatus, comprising a; small tub adapted to receive clothes but lackingcapacity for sufllcient washing fluid.

to wash the clothes, means in tile tub rotatable therewith for agitating the contents thereof, mechanism to effect oscillation of said agitating means, a tank having a capacity many times that of the tub adapted to contain the complete washing supply of cleansing liquid, and means for forcing substantially continuous rapid circulation of the cleansing liquid in a course from the tank to the tub and from the latter back into the tank during the operation of the agitating means, whereby a batch of clothes in the tub may be subjected to. a volume .of changing liquid many times greater than the capacity of 'the tub during the period of operation of the agitating means:-

2-. A self -contained laundry apparatus comprising a small rotatable tub adapted to'receive clothes but lacking capacity for sufiicient washing fluid to wash the clothes, means in the-tub rotatable therewith for agitating the contents of the tub, mechanism to eifect' oscillation or rapid liquid in a course from and back to the tank the movement of the tub, and instrumentalities for stopping the supply of liquid to the tub during the rapidly rotating phase of its movement while the second-mentioned pump is drawing the liquid away from the tub and returning it to said tank, the tub beingformed with a rim outlet to prevent excessive sudsing during the washing phase of the movement thereof.

cabinet structure and having a part adapted to be rotated at high speed, separate compartments for liquids symmetrically disposed. on opposite sides of said treating unit and spaced outwardly thereof from said rotatable part, means for gaining access tothe respective compartments and clothes-treating unit at the top of the cabinet structure, and means for operating the clothestreating unit while stabilized by the, compartments and the contents thereof.

4. Laundry apparatus comprising a cabinet structure, a clothes-treating unit centrally of said cabinet structure and having a part adapted to be rotated at high speed,laterally spaced separate compartments for liquids symmetrically disposed on each of opposite sides of said treating unit and" spaced .outwardly thereof from said rotatable part, the compartments on each side of said treata ing unit being arranged on opposite sides of the rotatable part, meansfor gaining access to the respective compartments of the clothes-treating unit at the top of the cabinet structure, means for conveying the liquids from the respective compartments to the clothes-treating unit, and means for operating the clothes-treating unit while. stabilized by the compartments and the I contents thereof.

- ally spaced separate compartments for liquidsv 5. Laundry apparatus comprising a cabinet structure having a top, a clothes-treating 'recep' tacle centrally of said cabinet structure extending downwardly from the top thereof and having a part adapted to be rotated at high speed, latersymmetrically disposed on each of opposite sides of said cabinet structure and spaced outwardly thereof from said receptacle, each of said comappreciably below the receptacle, means for gaina 99 partments extending downwardly from the top ing access to the respective compartments and to the clothes-treating unit at the top of the cabinet structure, and means for operating the clothes-treating unit while stabilized by the cornpartments and the contents thereof.

. HENRY. W. ALTORFER.

3. Laundry apparatus comprising a cabinet structure, a clothes-treating unit centrally of said 

